DE102005003286B4 - Container for a device for automated freezing or cryogenic substitution - Google Patents

Abstract

A container (50) for an apparatus for automated freezing or low-temperature absorption, wherein the container (50) is designed as an upwardly open pot (51), characterized in that an insert (55) is provided for the pot (51), dividing the container (50) into a first sector (52) and a second sector (53), wherein the first sector (52) is formed by the insert (55) in the pot (51), the first sector (52 ) has at least one holding position (56) for a sample container (2), and that the second sector (53) is a circular sector (60) which is formed by the part (55) of the insert (55) free, wherein in Annular ring sector (60) a plurality of reservoir (20) are arranged directly adjacent to each other and have the shape of a circular ring sector, and that the container (50) in the neck of a Dewar vessel (1) can be arranged.

Description

The The invention relates to a container for a device for automated freezing or cryogenic dosing. in the In particular, the invention relates to a container for a device for automated Freezing or cryogenic absorption, where the container as an upwardly open pot is formed.

The brochure to Leica EM AFS discloses a device according to the prior art. One Dewar tube is with liquid Nitrogen filled, wherein the dewar neck has a chamber or a container, which on a certain temperature can be brought. The temperature range ranges from -140 ° C up to + 65 ° C. The desired Temperature adjustment is via a control circuit and built-in heating elements. A supply of reagents in the chamber or container is not scheduled.

The German utility model DE 91 04 344 U1 discloses a cooling device for sample preparation for an electron microscope. The cooling device comprises a holding insert which is divided into at least two segments. Both segments are provided with openings, of which the openings in a segment serve to hold a container for the samples to be freeze-dried. In the openings of the other segment storage vessels are held with reagents. Thus, the samples and the reagents are cooled down to the required working temperature. An automatic transfer of the reagents from one area of the container to the next is not disclosed.

From the DE 34 25 744 C2 a device for dewatering and / or polymerization embedding biological samples at low temperatures is known. However, a space-saving arrangement of the samples and reagents is not disclosed.

This also applies to the DE 91 04 344 U1 , which describes a cooling device for sample preparation for an electron microscope.

task The present invention is therefore to a container create that for automation of manual activities in the freezer or low-temperature substitution is suitable. Furthermore, the container should be like this be designed that all for the automation of necessary reagents and samples in freezing or cryogenic substitution placed on the narrow space of the container are.

The The above object is achieved by a container for a device for automated Freezer or cryogenic solution solved the characteristics of the claim 1 includes.

It is beneficial if the container is divided into a first sector and a second sector, wherein at least one sample container in the first sector and in the second sector at least one storage container is arranged, and the container can be used in a chamber in the neck of a Dewar vessel or even this chamber forms.

Of the first sector is formed by an insert in the container, the least a stop position for the sample container having. For better utilization of the available space points the insert has two holding positions for the sample container. The insert has essentially the shape of a circular sector. The circular sector has an opening angle of less than 180 ° and has a center axis formed substantially with a Axis of an apparatus for automated freezing or cryogenic absorption flees.

Of the second sector is a circular sector that is free from the use Part of the container includes. In the circular sector several reservoirs are immediate arranged adjacent to each other.

The reservoir have a closable opening, through the liquid is removable or traceable. The openings are arranged on a radius of the open-topped pot. The storage containers have a base area in the form of a circular ring sector.

Of the Use For the sample container, the sample container itself and the reservoir are each in one piece made of a plastic.

Further Advantages and advantageous embodiments of the invention the dependent claims are taken and are the subject of the following figures as well their descriptions.

It show in detail:

1 a cross section through a dewar vessel;

2 a schematic representation of a Dewar vessel on which the device for automated freezing or cryogenic absorption is set up;

3 shows a perspective view of the container for receiving at least one sample container and at least one reservoir;

4 shows a plan view of the container for receiving at least one sample container and at least one storage container;

5a a sectional view of a first embodiment of the insert for the sample container, wherein in use a first embodiment of the compartments for receiving a sample is shown;

5b a sectional view of a second embodiment of the insert for the sample container, wherein in use a second embodiment of the compartments for receiving a sample is shown;

6a a top perspective view of the first embodiment of the compartments;

6b a perspective bottom view of the first embodiment of the compartments;

7 an enlarged, perspective bottom view of part of the compartments; and

8th a perspective view of the insert for receiving the at least one holding position for the sample container.

1 shows a cross section through a possible embodiment of a Dewar vessel 1 , In the following description, like reference numerals are used for like elements. In the 1 shown cooling device used for freezing or cryogenic substitution of biological and / or other aqueous samples. The Dewar vessel comprises an inner container 1 ₂ and an outer container 1 ₁ , The inner container is filled with a liquid coolant, preferably liquid nitrogen 3 is, filled. In the neck of the Dewar vessel 1 is a chamber 5 used. The chamber 5 is cup-shaped and has a solid bottom 5 ₁ , The chamber 5 is open at the top and can be insulated from the ambient temperature with a lid 6 be closed. The chamber 5 serves to accommodate one or more sample containers 2 in which there are samples 30 for freezing or cryogenic substitution. With the ground 5 ₁ the chamber 5 is a first thermal conductor 7 connected. At the bottom 5 ₁ the chamber 5 opposite end of the first Wärmeleitstabs 7 is a platform 8th intended. The platform 8th can be detachable with the first heat conductor 7 be connected. Furthermore, it is conceivable that the first heat-conducting rod 7 and the platform 8th are integrally formed. Above the platform 8th is the first thermal conductor 7 with insulation 12 surround. The insulation 12 serves to insulate the first thermal conductor 7 against the liquid nitrogen 3 or the cold nitrogen gas 3 ₁ , Through the insulation 12 the heat flow is used to cool the chamber 5 or of the soil 5 ₁ mainly via the platform 8th directed. The cooling performance can therefore advantageously by changing the geometric dimensions or by choosing a suitable material for the first Wärmeleitstab 7 be determined. The temperature in the chamber 5 can by operating at least one heating element 14 be managed. Likewise, at least one temperature sensor 15 provided, which is used for temperature measurement. The temperature sensor 15 can be designed as a thermocouple or resistance temperature sensor. The temperature signal is used as feedback for a control electronics 16 used the temperature of the chamber 5 by adjusting the heating power of the heating element 14 controls. The length of the first Wärmeleitstabs 7 is advantageously chosen so that the platform 8th only from a certain level in the liquid nitrogen 3 dips. At high level the platform dives 8th into the liquid nitrogen 3 one and the chamber 5 is about the first heat conductor 7 directly to the liquid nitrogen 3 coupled. When the level is low, the platform stands 8th in interaction with the cold nitrogen gas 3 ₁ , The cold nitrogen gas 3 ₁ is due to the heat flow from the chamber 5 in the inner container 1 ₂ of the Dewar vessel 1 heated. By convection and interaction with the wall of the inner container 1 ₂ This warming is again in the liquid nitrogen 3 fed back and leads to an increase in the evaporation rate. This results in an equilibrium temperature of the platform 8th and the chamber 5 , which are based on the current level of liquid nitrogen 3 in the inner container 1 ₂ is largely independent. It goes without saying that the heat coupling between the chamber 5 and the liquid nitrogen 3 at high level is much stronger than at low level. Therefore, at high levels lower temperatures in the chamber 5 be achieved. On the other hand, the consumption of liquid nitrogen at low level is lower.

This arrangement is advantageous in that the lowest process temperatures (-90 ° C and lower) are required in standard substitution processes at the beginning of the processes. The temperature is increased during the substitution processes. Because during the process also liquid nitrogen 3 is consumed, reflected by the first thermal conductor 7 and the platform 8th achievable cooling performance the temperature profile of the substitution process again. At the same time, through the insulation 12 even at high level, the coupling to the liquid nitrogen 3 limited. Therefore, even in this situation, high temperatures can be set without the required heating power of the heating element 14 and nitrogen consumption go beyond a reasonable scope.

2 shows a schematic representation of a Dewar vessel 1 on which the device 10 to the automated freezing or cryogenic sub institution is set up. Into the throat 1 ₃ of the Dewar vessel 1 is a chamber 5 used. The chamber 5 is cup-shaped and has a solid bottom 5 ₁ , The chamber 5 is open to the top The chamber 5 is designed as a container, the at least one sample container 2 and at least one storage container 20 includes. It is also conceivable that the container, the at least one sample container 2 and the at least one reservoir 20 includes from the chamber 5 is formed separately and used in this. A movable transfer container 35 is for the automated exchange of at least one liquid between the at least one sample container 2 and the at least one storage container 20 intended. The device 10 Can be fixed to the dewar 1 be connected. Likewise, it is conceivable that the device 10 from the Dewar tube 1 is designed removable. The device 10 is designed as a module, the z. B. by the user when needed on a Dewar vessel 1 can be set. The transfer container 35 is a syringe or a pipette. The suction or ejection of the liquid from the transfer container 35 is motor, pneumatic or hydraulic. This is the device 10 with an actuating element 36 provided with the motor, pneumatic or hydraulic suction or ejection of the liquid from the transfer container 35 he follows. It is a control unit 38 provided that the fluid transfer between the at least one sample container 2 and the at least one storage container 20 remotely controlled. The transfer container 35 moves back and forth accordingly, allowing fluid transfer. Along an axis 37 can the transfer container 35 move up and down. The control unit 38 it is the one programming a time sequence of transfer steps between the at least one reservoir 20 and the at least one sample container 2 allows.

3 shows a perspective view of the container 50 for receiving at least one sample container 2 and at least one storage container 20 , The container 50 is according to the embodiment shown here as an upwardly open pot 51 educated. The container 50 is in a first sector 52 and a second sector 53 divided. In the first sector 52 is the at least one sample container 2 intended. In the second sector 53 are the reservoirs 20 intended. The sample containers 2 are suitable for holding different types of sample containers. The reservoir 20 are designed as bottles and in the second sector 53 used. The second sector 53 has the shape of a circular ring sector 60 (please refer 4 ), so that also each of the reservoir 20 has the shape of a circular ring sector. The first sector 52 is through an insert 55 in the pot 51 formed, with the use 55 at least one stop position 56 for the sample container 2 having. In the preferred embodiment, the insert has 55 two stop positions 56 for the sample container 2 , The circular sector of the mission 55 has an opening angle of less than 180 °. Furthermore, the insert has 55 a center axis 58 has formed substantially with an axis 37 the device 10 aligned for automated freezing or cryogenic absorption.

4 shows a plan view of the container 50 for receiving at least one sample container 2 and at least one storage container 20 , The second sector 53 is, as already mentioned, a circular ring sector 60 who's the one from the deployment 55 free part of the pot 51 includes. In the circular sector 60 are several storage tanks 20 arranged directly adjacent to each other. Every reservoir 20 has a closable opening 45 by which liquid is removable or traceable. The openings 45 are on a radius of the open-topped pot 51 arranged. Each of the sample containers 2 is with an insert 65 to store and / or hold samples during freezing or cryogenic dosing. The use 65 for the sample container 2 is made in one piece from a plastic. As plastic for the production of the inserts 65 Polyethylene or polypropylene is preferably used. Likewise, the reservoirs 20 from a plastic, such as. As polyethylene or polypropylene. The sample containers 2 are also integrally made of a plastic, such. As polyethylene or polypropylene. The stakes 65 each have several compartments 70 on which serve for receiving or holding samples. The sections 70 are on the job 65 evenly and radially arranged.

5a shows a sectional view of a first embodiment of the insert 65 for the sample container 2 , being in use a first version of the compartments 70 is shown for receiving a sample. The sections 70 according to the first embodiment have the shape of a cylinder 73 , The sections 70 are on a common ground 71 arranged. Each of the radially arranged compartments 70 towers over the ground 71 in the direction of a floor 200 of the sample container 2 , Every Gefach 70 has on the ground 75 of the cylinder 73 a sample compartment 77 formed, that of several openings 79 is surrounded. The openings 79 serve to get liquid out of the compartments 70 can escape and get on the ground 200 of the sample container 2 collects. The excess liquid can be removed by means of the device 10 via a central cylinder 78 of the insert 65 be removed or supplied.

5b shows a sectional view of a second embodiment of the insert 65 for the sample container 2 , being in use 65 a second off management of the divisions 70 is shown for receiving a sample. On a wall 201 of the sample container 2 are several projections 76 shaped, the use 65 on the ground 200 of the sample container 2 Hold so that it is not flooded when filling the liquid. The sections 70 have a groove 74 formed under which the samples are clamped during freezing or cryogenic absorption.

6a shows a top perspective view of the first embodiment of the compartments 70 of the insert 65 , The sections 70 have the shape of a cylinder 73 and are radial about a central cylinder 78 of the insert 65 arranged. The insert essentially has the diameter of the sample container 2 , so that thereby a tight fit is ensured in this.

6b shows a perspective bottom view of the first embodiment of the compartments 70 of the insert 65 , The sections 70 are on a common ground 71 arranged. Every Gefach 70 has on the ground 75 of the cylinder 73 a sample compartment 77 formed, that of several openings 79 is surrounded. The sample compartment 77 towers over the ground 71 of the insert 65 ,

7 shows an enlarged, perspective bottom view of a part of the compartments 70 the first embodiment. The sample compartment 77 consists of a circular section 90 , the central on the ground 75 of the cylinder 73 is trained. At the circular section 90 is an approximately semicircular section 91 trained, with respect to the use 65 pointing radially outwards. The circular section 90 is in the area where the circular section 90 , free from the semicircular section 91 is from a variety of openings 79 surround.

8th shows a perspective view of the first sector 52 for receiving the at least one holding position 56 for the sample container 2 , The first sector 52 is as an insert 55 for the container 50 educated. Each of the stop positions 56 for the sample container 2 has several retaining elements 62 formed, with the corresponding retaining tabs 63 interact on the sample container 2 are formed. Due to the mechanical interaction of the holding elements 62 and the retaining tabs 63 will ensure a secure and tight fit of the sample container 2 in the first sector 52 achieved.

Claims (13)

Container ( 50 ) for an apparatus for automated freezing or cryogenic absorption, wherein the container ( 50 ) as an open-topped pot ( 51 ), characterized in that an insert ( 55 ) for the pot ( 51 ) is provided, the container ( 50 ) into a first sector ( 52 ) and a second sector ( 53 ), the first sector ( 52 ) because of the engagement ( 55 ) in the pot ( 51 ) is formed, that the first sector ( 52 ) at least one stop position ( 56 ) for a sample container ( 2 ), and that the second sector ( 53 ) a circular ring sector ( 60 ), that of the mission ( 55 ) free part of the pot ( 51 ), where in the circular sector ( 60 ) several storage containers ( 20 ) are arranged directly adjacent to each other and have the shape of a circular ring sector, and that the container ( 50 ) in the neck of a Dewar vessel ( 1 ) can be arranged. Container ( 50 ) according to claim 1, characterized in that the container in a in the neck of the Dewar vessel ( 1 ) located chamber ( 5 ) is used. Container ( 50 ) according to claim 1, characterized in that the insert ( 55 ) two stop positions ( 56 ) for the sample container ( 2 ) having. Container ( 50 ) according to one of claims 1 to 3, characterized in that the insert ( 55 ) has substantially the shape of a circular sector. Container ( 50 ) according to claim 4, characterized in that the circular sector has an opening angle of less than 180 ° and a center axis ( 58 ) formed substantially with an axis ( 37 ) a device ( 10 ) is aligned for automated freezing or cryogenic dosing. Container ( 50 ) according to claim 1, characterized in that the storage containers ( 20 ) a closable opening ( 45 ), through which liquid is removable or traceable, and that the openings ( 45 ) on a radius ( 61 ) of the open-topped pot ( 51 ) are arranged. Container ( 50 ) according to one of claims 1 to 6, characterized in that each of the holding positions ( 56 ) for the sample container ( 2 ) a plurality of retaining elements ( 62 ) formed with corresponding retaining tabs ( 63 ) interacting with the sample container ( 2 ) are formed. Container ( 50 ) according to claim 7, characterized in that three retaining elements ( 62 ) evenly at the periphery of the holding positions ( 56 ) are distributed. Container ( 50 ) according to one of claims 1 to 8, characterized in that in the sample container ( 2 ) an insert ( 65 ) can be used to store and / or hold samples during freezing or cryogenic subsidence. Container ( 50 ) according to claim 9, characterized in that the insert ( 65 ) for the sample container ( 2 ) is made in one piece from a plastic. Container ( 50 ) according to claim 9, characterized in that the sample container ( 2 ) is made in one piece from a plastic. Container ( 50 ) according to claim 10, characterized in that the insert ( 65 ) several compartments ( 70 ) for holding or holding samples, and that the compartments ( 70 ) on the mission ( 65 ) are arranged uniformly and radially. Container ( 50 ) according to claim 12, characterized in that the compartments ( 70 ) the shape of a cylinder ( 73 ) that the divisions ( 70 ) on a common ground ( 71 ) are arranged such that each of the radially arranged compartments ( 70 ) the ground ( 71 ) and that every Gefach ( 71 ) on the ground ( 75 ) of the cylinder ( 73 ) a sample compartment ( 77 ) formed by several openings ( 79 ) is surrounded.